cameras camera obscura first known photograph pinhole

5
1 Cameras (Reading: Chapter 1) Goal: understand how images are formed Camera obscura dates from 15 th century Basic abstraction is the pinhole camera Perspective projection is a simple mathematical operation that discards one dimension The human eye functions very much like a camera http://www.acmi.net.au/AIC/CAMERA_OBSCURA.html (Russell Naughton) Camera Obscura "When images of illuminated objects ... penetrate through a small hole into a very dark room ... you will see [on the opposite wall] these objects in their proper form and color, reduced in size ... in a reversed position, owing to the intersection of the rays". Da Vinci Slide credit: David Jacobs http://brightbytes.com/cosite/collection2.html (Jack and Beverly Wilgus) Jetty at Margate England, 1898. Slide credit: David Jacobs First known photograph Pinhole cameras Pinhole camera - box with a small hole in it Image is upside down, but not mirrored left-to-right Question: Why does a mirror reverse left-to-right but not top-to-bottom? Pinhole camera in 2D X’ = (f’ / Z) X

Upload: others

Post on 11-Feb-2022

22 views

Category:

Documents


1 download

TRANSCRIPT

Page 1: Cameras Camera Obscura First known photograph Pinhole

1

Cameras(Reading: Chapter 1)

• Goal: understand how images are formed

• Camera obscura dates from 15th century

• Basic abstraction is the pinhole camera

• Perspective projection is a simple mathematical operation that discards one dimension

• The human eye functions very much like a camera

http://www.acmi.net.au/AIC/CAMERA_OBSCURA.html (Russell Naughton)

Camera Obscura

"When images of illuminated objects ... penetrate through a small hole into a very dark room ... you will see [on the opposite wall] these objects in their proper form and color, reduced in size ... in a reversed position, owing to the intersection of the rays". Da Vinci

Slide credit: David Jacobs

http://brightbytes.com/cosite/collection2.html (Jack and Beverly Wilgus)

Jetty at Margate England, 1898.

Slide credit: David Jacobs

First known photograph

Pinhole cameras

• Pinhole camera - box with a small hole in it

• Image is upside down, but not mirrored left-to-right

• Question: Why does a mirror reverse left-to-right but not top-to-bottom?

Pinhole camera in 2D

X’ = (f’ / Z) X

Page 2: Cameras Camera Obscura First known photograph Pinhole

2

Pinhole camera in 2D(with reflected image plane)

The image is the same after reflection of the image plane, except that image is the right way up!

Distant objects are smaller

Size is inversely proportional to distance.

Parallel lines meet

Example of the film plane drawnin front of the focal point.Moving the film plane merelyscales the image.

Vanishing points

• each set of parallel lines meets at a different point– The vanishing point for this

direction

• Sets of parallel lines on the same plane lead to collinear vanishing points. – The line is called the

horizon for that plane

• Good ways to spot faked images– scale and perspective don’t

work

– vanishing points behave badly

Slide credit: David Jacobs

Properties of perspective projection

• Points project to points• Lines project to lines• Planes project to the whole or half image• Angles are not preserved• Degenerate cases

– Line through focal point projects to a point.– Plane through focal point projects to line

Page 3: Cameras Camera Obscura First known photograph Pinhole

3

The equation of perspective projection Weak perspective

Assume object points are all at same depth -z0

Orthographic projection Pros and Cons of These Models

• Weak perspective (including orthographic) has simpler mathematics– Accurate when object is small relative to its distance.– Most useful for recognition.

• Perspective is much more accurate for scenes.– Used in structure from motion.

• When accuracy really matters, we must model the real camera– Use perspective projection with other calibration

parameters (e.g., radial lens distortion)

Why not use pinhole cameras?

If pinhole is too big -many directions areaveraged, blurring the image

Pinhole too small-diffraction effectsblur the image

Generally, pinhole cameras are dark, because a very small set of rays from a particular point hits the screen.

The reason for lenses

Page 4: Cameras Camera Obscura First known photograph Pinhole

4

Snell’s law

n1 and n2 are the indices of refraction of each material

Pinhole model with a single lens

A lens follows the pinhole model for objects that are in focus.

An out-of-focus lens

An image plane at the wrong distance means that rays from different parts of the lens create a blurred region (the “point spread function”).

Spherical aberration

Historically, spherical lenses were the only easy shape to manufacture, but are not correct for perfect focus.

Lens systems

• A good camera lens may contain 15 elements and cost a thousand dollars

• The best modern lenses may contain aspherical elements

Vignetting

• Human vision is quite insensitive to slow change in brightness.• However, computer vision systems may be affected.

Page 5: Cameras Camera Obscura First known photograph Pinhole

5

Other (possibly annoying) phenomena

• Chromatic aberration– Light at different wavelengths follows different paths; hence, some

wavelengths are defocussed

• Scattering at the lens surface– Some light entering the lens system is reflected off each surface it

encounters (Fresnel’s law gives details)

– Cameras: coat the lens, interior

– Human vision: lives with it (various scattering phenomena are visible in the human eye)

• Geometric phenomena (radial distortion, etc.) http://www.cas.vanderbilt.edu/bsci111b/eye/human-eye.jpg

Human Eye• The eye has an iris

like a camera• Focusing is done by

changing shape of lens

• Retina contains cones (mostly used) and rods (for low light)

• The fovea is small region of high resolution containing mostly cones

• Optic nerve: 1 million flexible fibres

Slide credit: David Jacobs

CCD Cameras

http://huizen.ddsw.nl/bewoners/maan/imaging/camera/ccd1.gif

Slide credit: David Jacobs